The present disclosure is directed to systems and methods for endovascular electroencephalography (EEG) and electrocorticography (ECoG) systems. In some embodiments, the disclosed systems include electrode arrays that are configured to record and/or stimulate brain tissue via placement within blood vessels of the brain. Venous and arterial EEG and ECoG electrodes, ambulatory EEG and ECoG systems, and transcutaneous access and signal control systems for general and ambulatory endovascular electroencephalography (EEG) and electrocorticography (ECoG), as well as endovascular neural stimulating electrodes are discussed.

Systems and methods for monitoring physiological indicators that a patient is in distress can include a distress monitor comprising a band configured to be placed about and in contact with a portion of a body of the patient; a plurality of sensors configured to measure changes in the physiological indicators of the patient; and a controller contained within an electronics region of the band, the controller being electronically connected to each of the plurality of sensors to receive a respective output signal from each; and a display configured to receive an output signal from the controller and to display an alert when the patient is displaying indicators of physiological distress.

The invention encompasses systems and methods allowing for minimally invasive insertion and functional optimization of implantable electrode arrays designed for placement within the subgaleal space to record brain electrical activity. The implantable arrays comprise a support structure capable of being implanted in the subgaleal space and comprising at least one reference element; at least one ground element; and one or more recording elements; and wherein said array is capable of detecting and/or transmitting a subgaleal electrical signal.

The invention encompasses systems and methods allowing for minimally invasive insertion and functional optimization of implantable electrode arrays designed for placement within the subgaleal space to record brain electrical activity. The implantable arrays comprise a support structure capable of being implanted in the subgaleal space and comprising at least one reference element; at least one ground element; and one or more recording elements; and wherein said array is capable of detecting and/or transmitting a subgaleal electrical signal.

A monitor device (6) for coupling to a sensor assembly of an ostomy appliance is disclosed. The monitor device comprises a housing, a processor arranged in said housing, and an appliance interface configured for coupling the monitor device to the sensor assembly. The appliance interface comprises a plurality of terminals for connecting with a plurality of electrodes of the sensor assembly. Further, the monitor device comprises a three-axis accelerometer (540) configured to generate a position signal. Further, a method for determining a rotational offset of a sensor assembly relative to an ostomy and a system comprising a monitor device and a sensor assembly is disclosed.

Provided are an electronic device, a method for pushing information, and related products. The method includes the following. A first set of data on multiple substances in a first position of a body of a user is obtained by scanning the first position with a substance detecting sensor. A body part corresponding to the first position is determined with a camera. Fitness plan is determined according to the first set of data and the body part and then pushed via a display.

Systems and methods for monitoring physiological indicators that a patient is in distress can include a distress monitor comprising a band configured to be placed about and in contact with a portion of a body of the patient; a plurality of sensors configured to measure changes in the physiological indicators of the patient; and a controller contained within an electronics region of the band, the controller being electronically connected to each of the plurality of sensors to receive a respective output signal from each; and a display configured to receive an output signal from the controller and to display an alert when the patient is displaying indicators of physiological distress.

The present disclosure is directed to systems and methods for endovascular electroencephalography (EEG) and electrocorticography (ECoG) systems. In some embodiments, the disclosed systems include electrode arrays that are configured to record and/or stimulate brain tissue via placement within blood vessels of the brain. Venous and arterial EEG and ECoG electrodes, ambulatory EEG and ECoG systems, and transcutaneous access and signal control systems for general and ambulatory endovascular electroencephalography (EEG) and electrocorticography (ECoG), as well as endovascular neural stimulating electrodes are discussed.

The invention encompasses systems and methods allowing for minimally invasive insertion and functional optimization of implantable electrode arrays designed for placement within the subgaleal space to record brain electrical activity. The implantable arrays comprise a support structure capable of being implanted in the subgaleal space and comprising at least one reference element; at least one ground element; and one or more recording elements; and wherein said array is capable of detecting and/or transmitting a subgaleal electrical signal.

A system for acquiring electrocardiograph (ECG) and bioimpedance (BI) data is disclosed. The system (an ECG/BI measurement system) can use as few as one or two pairs of electrodes, permitting wearable devices employing the ECG/BI measurement system to be made into smaller, more comfortable, and more inconspicuous formats, as well as decreasing potential failure points in the measurement of electrical signals conducted between the system and the user. The system can measure both ECG and BI data using at least one shared pair of electrodes. In some cases, ECG and BI data are separately extracted from a measured signal across a shared pair of electrodes, while another pair of electrodes is being driven with a supply current. In other cases, internal switching can automatically switch a pair of electrodes between ECG-measuring circuitry and BI-measuring circuitry, such as based on a clock signal or other trigger.